Evolution of chemically induced cracks in alkali feldspar: thermodynamic analysis

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Authors

  • Rainer Abart
  • Elena Petrishcheva
  • Gerlinde Habler
  • Christoph Sutter
  • Jozef Predan
  • Marko Kegl
  • Franz G. Rammerstorfer

Organisational units

External Organisational units

  • Universität Wien
  • Universität Maribor
  • Institute of Materials Science and Technology

Abstract

A system of edge cracks was applied to polished (010) surfaces of K-rich gem-quality alkali feldspar by diffusion-mediated cation exchange between oriented feldspar plates and a Na-rich NaCl–KCl salt melt. The cation exchange produced a Na-rich layer at and beneath the specimen surface, and the associated strongly anisotropic lattice contraction lead to a tensile stress state at the specimen surface, which induced fracturing. Cation exchange along the newly formed crack flanks produced Na-enriched diffusion halos around the cracks, and the associated lattice contraction and tensile stress state caused continuous crack growth. The cracks nucleated with non-uniform spacing on the sample surface and quickly attained nearly uniform spacing below the surface by systematic turning along their early propagation paths. In places, conspicuous wavy cracks oscillating several times before attaining their final position between the neighboring cracks were produced. It is shown that the evolution of irregularly spaced towards regularly spaced cracks including the systematic turning and wavyness along the early propagation paths maximizes the rate of free energy dissipation in every evolutionary stage of the system. Maximization of the dissipation rate is suggested as a criterion for selection of the most probable evolution path for a system undergoing chemically induced diffusion mediated fracturing in an anisotropic homogeneous brittle material.

Details

Original languageEnglish
Article number14
Number of pages15
JournalPhysics and Chemistry of Minerals
Volume49.2022
Issue number14
DOIs
Publication statusPublished - 3 May 2022